Spatial noise correlations beyond nearest neighbors in 28Si/ Si-Ge spin qubits

J. S. Rojas-Arias; A. Noiri; P. Stano; T. Nakajima; J. Yoneda; K. Takeda; T. Kobayashi; A. Sammak; G. Scappucci

doi:10.1103/PhysRevApplied.20.054024

Spatial noise correlations beyond nearest neighbors in 28Si/ Si-Ge spin qubits

J. S. Rojas-Arias, A. Noiri, P. Stano, T. Nakajima, J. Yoneda, K. Takeda, T. Kobayashi, A. Sammak, G. Scappucci

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Abstract

We detect correlations in qubit-energy fluctuations of non-neighboring qubits defined in isotopically purified Si/Si-Ge quantum dots. At low frequencies (where the noise is strongest), the correlation coefficient reaches 10% for a next-nearest-neighbor qubit-pair separated by 200 nm. Correlations with the charge-sensor signal reach up to 70%, proving that the observed noise is of electrical origin. A simple theoretical model quantitatively reproduces the measurements and predicts a polynomial decay of correlations with interqubit distance. Our results quantify long-range correlations of noise in quantum-dot spin-qubit arrays, essential for their scalability and fault tolerance.

Original language	English
Article number	054024
Journal	Physical Review Applied
Volume	20
Issue number	5
DOIs	https://doi.org/10.1103/PhysRevApplied.20.054024
Publication status	Published - 2023

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title = "Spatial noise correlations beyond nearest neighbors in 28Si/ Si-Ge spin qubits",

abstract = "We detect correlations in qubit-energy fluctuations of non-neighboring qubits defined in isotopically purified Si/Si-Ge quantum dots. At low frequencies (where the noise is strongest), the correlation coefficient reaches 10% for a next-nearest-neighbor qubit-pair separated by 200 nm. Correlations with the charge-sensor signal reach up to 70%, proving that the observed noise is of electrical origin. A simple theoretical model quantitatively reproduces the measurements and predicts a polynomial decay of correlations with interqubit distance. Our results quantify long-range correlations of noise in quantum-dot spin-qubit arrays, essential for their scalability and fault tolerance.",

author = "Rojas-Arias, {J. S.} and A. Noiri and P. Stano and T. Nakajima and J. Yoneda and K. Takeda and T. Kobayashi and A. Sammak and G. Scappucci",

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AU - Rojas-Arias, J. S.

AU - Noiri, A.

AU - Stano, P.

AU - Nakajima, T.

AU - Yoneda, J.

AU - Takeda, K.

AU - Kobayashi, T.

AU - Sammak, A.

AU - Scappucci, G.

PY - 2023

Y1 - 2023

N2 - We detect correlations in qubit-energy fluctuations of non-neighboring qubits defined in isotopically purified Si/Si-Ge quantum dots. At low frequencies (where the noise is strongest), the correlation coefficient reaches 10% for a next-nearest-neighbor qubit-pair separated by 200 nm. Correlations with the charge-sensor signal reach up to 70%, proving that the observed noise is of electrical origin. A simple theoretical model quantitatively reproduces the measurements and predicts a polynomial decay of correlations with interqubit distance. Our results quantify long-range correlations of noise in quantum-dot spin-qubit arrays, essential for their scalability and fault tolerance.

AB - We detect correlations in qubit-energy fluctuations of non-neighboring qubits defined in isotopically purified Si/Si-Ge quantum dots. At low frequencies (where the noise is strongest), the correlation coefficient reaches 10% for a next-nearest-neighbor qubit-pair separated by 200 nm. Correlations with the charge-sensor signal reach up to 70%, proving that the observed noise is of electrical origin. A simple theoretical model quantitatively reproduces the measurements and predicts a polynomial decay of correlations with interqubit distance. Our results quantify long-range correlations of noise in quantum-dot spin-qubit arrays, essential for their scalability and fault tolerance.

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VL - 20

JO - Physical Review Applied

JF - Physical Review Applied

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Spatial noise correlations beyond nearest neighbors in 28Si/ Si-Ge spin qubits

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